Limitless Lab Grown Blood Is
Now ‘Tantalizingly Close’ After 20 Years
By Shelly Fan, June 1, 2017
Harvard Medical School
Weill
Cornell Medical
College
By Shelly Fan, June 1, 2017
Blood stem cells are things of
wonder: hidden inside each single cell is the power to reconstitute an entire
blood system, like a sort of biological big bang.
Yet with great power comes greater
vulnerability. Once these “master cells” are compromised, as in the case of
leukemia and other blood disorders, treatment options are severely limited.
A bone marrow transplant is often the
only chance for survival. The surgery takes a healthy donor’s marrow—rich with
blood stem cells—and reboots the patient’s blood system. Unfortunately, like
organ transplants, finding a matching donor places a chokehold on the entire
process.
According to Dr. George Daley at
For 20 years, scientists have been
trying to find a way to beat the odds. Now, two studies published in Nature
suggest they may be “tantalizingly close” to being able to make a limitless
supply of blood stem cells, using the patient’s own healthy tissues.
"This step opens up an
opportunity to take cells from patients with genetic blood disorders, use gene
editing to correct their genetic defect and make functional blood cells,"
without depending on donors, says Dr. Ryohichi Sugimura at Boston Children’s
Hospital, who authored one of the studies with Daley.
Using a magical mix of seven proteins
called transcription factors, the team coaxed lab-made human stem cells into
primordial blood cells that replenished themselves and all components of blood.
A second study led by Dr. Shahin
Rafii, a stem cell scientist at
“This is the first time researchers
have checked all the boxes and made blood stem cells,” says Dr. Mick Bhatia at McMaster University
Educating Blood Cells
The life of a blood stem cell starts
as a special cell nestled on the walls of a large blood vessel—the dorsal
aorta.
Under the guidance of chemical
signals, these cells metamorphose into “immature” baby blood stem cells, like
caterpillars transforming into butterflies. The exact conditions that prompt
this birthing process are still unclear and is one of the reasons why lab-grown
blood stem cells have been so hard to make.
These baby blood stem cells don’t yet
have the full capacity to reboot blood systems. To fully mature, they have to
learn to respond to all sorts of commands in their environment, like toddlers
making sense of the world.
Some scientists liken this learning
process to going to school, where different external cues act as “textbooks” to
train baby blood stem cells to correctly respond to the body.
For example, when should they divide
and multiply? When should they give up their “stem-ness,” instead transforming
into oxygen-carrying red blood cells or white blood cells, the immune
defenders?
The Long Way
Both new studies took aim at cracking
the elusive curriculum.
In the first study, Daley and team
started with human skin and other cells that have been transformed back into
stem cells (dubbed “iPSCs,” or induced pluripotent stem cells). Although iPSCs
theoretically have the ability to turn into any cell type, no one has
previously managed to transform them into blood stem cells.
“A lot of people have become jaded,
saying that these cells don’t exist in nature and you can’t just push them into
becoming anything else,” says Bhatia.
All cells in an organism share the
same genes. However, for any given cell only a subset of genes are turned into
proteins. This process is what gives cells their identities—may it be a heart
cell, liver cell, or blood stem cell.
Daley and team focused on a family of
transcription factors. Similar to light switches, these proteins can flip genes
on or off. By studying how blood vessels normally give birth to blood stem
cells, they found seven factors that encouraged iPSCs to grow into immature
blood stem cells.
Using a virus, the team inserted
these factors into their iPSCs and injected the transformed cells into the bone
marrow of mice. These mice had been irradiated to kill off their own blood stem
cells to make room for the lab-grown human replacements.
In this way, Daley exposed the
immature cells to signals in a blood stem cell’s normal environment. The bone
marrow acts like a school, explains Drs. Carolina Guibentif and Berthold Göttgens
at the University
of Cambridge
It worked. In just twelve weeks, the
lab-made blood stem cells had fully matured into master cells capable of making
the entire range of cells normally found in human blood. What’s more, when
scientists took these cells out and transplanted them into a second recipient,
they retained their power.
“This a major step forward compared
with previous methods,” says Guibentif.
Direct Route
In contrast, the second study took a
more direct route. Rafii and team took cells lining a mouse’s vessels, based on
the finding that these cells normally turn into blood stem cells during
development.
With a set of four transcription
factors, the team directly reprogrammed them into baby blood stem cells, bypassing
the iPSC stage.
These factors act like a maternity
ward, allowing the blood stem cells to be born, says Guibentif.
To grow them to adulthood, Rafii and
team laid the cells onto a blanket of supporting cells that mimics the blood
vessel “nursery.” Under the guidance of molecular cues secreted by these
supporting cells, the blood stem cells multiplied and matured.
When transplanted into short-lived
mice without a functional immune system, the cells sprung to action. In 20
weeks, the mice generated an active immune response when given a vaccine.
What’s more, they went on to live a healthy 1.5 years—roughly equivalent to 60
years old for a human.
Limitless
Blood
Rafii is especially excited about
using his system to finally crack the stem cell learning curriculum.
If we can figure out the factors that
coax stem cells to divide and mature, we may be able to unravel the secrets of
their longevity and make full-fledged blood stem cells in a dish, he says.
Calling both experiments a
“breakthrough,” Guibentif says, “this is something people have been trying to
achieve for a long time.”
However, she points out that both
studies have caveats. A big one is cancer. The transcription factors that turn
mature cells into stem cells endow them with the ability to multiply
efficiently—a hallmark of cancerous cells. What’s more, the virus used to
insert the factors into cells may also inadvertently turn on cancer-causing
genes.
That said, neither team found
evidence of increased risk of blood cancers. Guibentif also acknowledges that
future studies could use CRISPR in place of transcription factors to transform
cells into blood stem cells on demand, further lowering the risk.
The techniques will also have to be
made more efficient to make lab-grown blood stem cells cost efficient. It’ll be
years until human use, says Guibentif.
Even so, the studies deter even the
most cynical of critics.
After 20 years, we’re finally
“tantalizingly close to generating bona fide human blood stem cells in a
dish," says Daley.
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